Methane oxidation by N2O over Fe-FER catalysts prepared by different methods: Nature of active iron species, stability of surface oxygen species and selectivity to products

[Display omitted] •Different iron sites formed over Fe-FER catalysts prepared by different methods.•Active oxygen species in Fe-FER-SSIE is more stable compared to Fe-FER-IE.•Higher yield of desired products was obtained over Fe-FER-SSIE than Fe-FER-IE. Catalysts with different iron species distribu...

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Bibliographic Details
Published inJournal of catalysis Vol. 400; pp. 10 - 19
Main Authors Zhao, Guangyu, Chodyko, Kerryn, Benhelal, Emad, Adesina, Adesoji, Kennedy, Eric, Stockenhuber, Michael
Format Journal Article
LanguageEnglish
Published Elsevier Inc 01.08.2021
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Summary:[Display omitted] •Different iron sites formed over Fe-FER catalysts prepared by different methods.•Active oxygen species in Fe-FER-SSIE is more stable compared to Fe-FER-IE.•Higher yield of desired products was obtained over Fe-FER-SSIE than Fe-FER-IE. Catalysts with different iron species distributions were developed by loading iron ions to ferrierite (FER) zeolite using liquid ion exchange (IE) and solid state ion exchange (SSIE) methods, which in turn facilitates to study the relation between the nature of iron sites with the formation and stability of surface oxygen species, based on the comparable investigation of catalytic activity and selectivity to products over the catalysts, and the characterisation results obtained from a variety of spectroscopic and solid characterization techniques. IR spectra and NH3-TPD profiles demonstrate a greater extent of exchange of protons in bridging OH positions by iron cations with the Fe-FER-SSIE, in comparison to Fe-FER-IE catalyst. The primary catalytic species present in Fe-FER-IE are isolated Fe species in cation exchange positions, as indicated by UV–vis spectra, while isolated and oligomeric extra-framework Fe species were present in Fe-FER-SSIE catalysts, which is consistent with H2-TPR profiles of N2O pre-treated catalysts and IR spectra of NO adsorption on the catalysts. N2O-TPD results demonstrate that the desorption of oxygen molecules (O2) released from surface oxygen species was observed at lower temperature and higher concentration from Fe-FER-IE than Fe-FER-SSIE. Higher ratio of N2O consumption/methane conversion over Fe-FER-IE was observed than Fe-FER-SSIE. With similar methane conversion, over Fe-FER-SSIE a higher selectivity to valuable products methanol, formaldehyde and dimethyl ether was observed than over Fe-FER-IE.
ISSN:0021-9517
1090-2694
DOI:10.1016/j.jcat.2021.04.019